// Copyright (c) 2012-2020 Ugorji Nwoke. All rights reserved.
// Use of this source code is governed by a MIT license found in the LICENSE file.

/*
Package codec provides a High Performance, Feature-Rich Idiomatic Go
codec/encoding library for binc, msgpack, cbor, json.

Supported Serialization formats are:

  - msgpack: https://github.com/msgpack/msgpack
  - binc: http://github.com/ugorji/binc
  - cbor: http://cbor.io http://tools.ietf.org/html/rfc7049
  - json: http://json.org http://tools.ietf.org/html/rfc7159
  - simple: (unpublished)

For detailed usage information, read the primer at http://ugorji.net/blog/go-codec-primer .

The idiomatic Go support is as seen in other encoding packages in
the standard library (ie json, xml, gob, etc).

Rich Feature Set includes:

  - Simple but extremely powerful and feature-rich API
  - Support for go 1.21 and above, selectively using newer APIs for later releases
  - Excellent code coverage ( ~ 85-90% )
  - Very High Performance, significantly outperforming libraries for Gob, Json, Bson, etc
  - Careful selected use of 'unsafe' for targeted performance gains.
  - 100% safe mode supported, where 'unsafe' is not used at all.
  - Lock-free (sans mutex) concurrency for scaling to 100's of cores
  - In-place updates during decode, with option to zero value in maps and slices prior to decode
  - Coerce types where appropriate e.g. decode an int in the stream into a
    float, decode numbers from formatted strings, etc
  - Corner Cases: Overflows, nil maps/slices, nil values in streams are handled correctly
  - Standard field renaming via tags
  - Support for omitting empty fields during an encoding
  - Encoding from any value and decoding into pointer to any value (struct,
    slice, map, primitives, pointers, interface{}, etc)
  - Extensions to support efficient encoding/decoding of any named types
  - Support encoding.(Binary|Text)(M|Unm)arshaler interfaces
  - Support using existence of `IsZero() bool` to determine if a zero value
  - Decoding without a schema (into a interface{}). Includes Options to
    configure what specific map or slice type to use when decoding an encoded
    list or map into a nil interface{}
  - Mapping a non-interface type to an interface, so we can decode appropriately
    into any interface type with a correctly configured non-interface value.
  - Encode a struct as an array, and decode struct from an array in the data stream
  - Option to encode struct keys as numbers (instead of strings) (to support
    structured streams with fields encoded as numeric codes)
  - Comprehensive support for anonymous fields
  - Fast (no-reflection) encoding/decoding of common maps and slices
  - Code-generation for faster performance, supported in go 1.6+
  - Support binary (e.g. messagepack, cbor) and text (e.g. json) formats
  - Support indefinite-length formats to enable true streaming (for formats
    which support it e.g. json, cbor)
  - Support canonical encoding, where a value is ALWAYS encoded as same sequence of bytes.
    This mostly applies to maps, where iteration order is non-deterministic.
  - NIL in data stream decoded as zero value
  - Never silently skip data when decoding. User decides whether to return an
    error or silently skip data when keys or indexes in the data stream do not
    map to fields in the struct.
  - Detect and error when encoding a cyclic reference (instead of stack overflow shutdown)
  - Encode/Decode from/to chan types (for iterative streaming support)
  - Drop-in replacement for encoding/json. `json:` key in struct tag supported.
  - Provides a RPC Server and Client Codec for net/rpc communication protocol.
  - Handle unique idiosyncrasies of codecs e.g. For messagepack,
    configure how ambiguities in handling raw bytes are resolved and provide
    rpc server/client codec to support msgpack-rpc protocol defined at:
    https://github.com/msgpack-rpc/msgpack-rpc/blob/master/spec.md

# Supported build tags

We gain performance by code-generating fast-paths for slices and maps of built-in types,
and monomorphizing generic code explicitly so we gain inlining and de-virtualization benefits.

The results are 20-50% performance improvements over v1.2.

Building and running is configured using build tags as below.

At runtime:

- codec.safe: run in safe mode (not using unsafe optimizations)
- codec.notmono: use generics code (bypassing performance-boosting monomorphized code)
- codec.notfastpath: skip fast path code for slices and maps of built-in types (number, bool, string, bytes)

Each of these "runtime" tags have a convenience synonym i.e. safe, notmono, notfastpath.
Pls use these mostly during development - use codec.XXX in your go files.

Build only:

- codec.build: used to generate fastpath and monomorphization code

Test only:

- codec.notmammoth: skip the mammoth generated tests

# Extension Support

Users can register a function to handle the encoding or decoding of
their custom types.

There are no restrictions on what the custom type can be. Some examples:

	type BisSet   []int
	type BitSet64 uint64
	type UUID     string
	type MyStructWithUnexportedFields struct { a int; b bool; c []int; }
	type GifImage struct { ... }

As an illustration, MyStructWithUnexportedFields would normally be
encoded as an empty map because it has no exported fields, while UUID
would be encoded as a string. However, with extension support, you can
encode any of these however you like.

There is also seamless support provided for registering an extension (with a tag)
but letting the encoding mechanism default to the standard way.

# Custom Encoding and Decoding

This package maintains symmetry in the encoding and decoding halfs.
We determine how to encode or decode by walking this decision tree

  - is there an extension registered for the type?
  - is type a codec.Selfer?
  - is format binary, and is type a encoding.BinaryMarshaler and BinaryUnmarshaler?
  - is format specifically json, and is type a encoding/json.Marshaler and Unmarshaler?
  - is format text-based, and type an encoding.TextMarshaler and TextUnmarshaler?
  - else we use a pair of functions based on the "kind" of the type e.g. map, slice, int64, etc

This symmetry is important to reduce chances of issues happening because the
encoding and decoding sides are out of sync e.g. decoded via very specific
encoding.TextUnmarshaler but encoded via kind-specific generalized mode.

Consequently, if a type only defines one-half of the symmetry
(e.g. it implements UnmarshalJSON() but not MarshalJSON() ),
then that type doesn't satisfy the check and we will continue walking down the
decision tree.

# RPC

RPC Client and Server Codecs are implemented, so the codecs can be used
with the standard net/rpc package.

# Usage

The Handle is SAFE for concurrent READ, but NOT SAFE for concurrent modification.

The Encoder and Decoder are NOT safe for concurrent use.

Consequently, the usage model is basically:

  - Create and initialize the Handle before any use.
    Once created, DO NOT modify it.
  - Multiple Encoders or Decoders can now use the Handle concurrently.
    They only read information off the Handle (never write).
  - However, each Encoder or Decoder MUST not be used concurrently
  - To re-use an Encoder/Decoder, call Reset(...) on it first.
    This allows you use state maintained on the Encoder/Decoder.

Sample usage model:

	// create and configure Handle
	var (
	  bh codec.BincHandle
	  mh codec.MsgpackHandle
	  ch codec.CborHandle
	)

	mh.MapType = reflect.TypeOf(map[string]interface{}(nil))

	// configure extensions
	// e.g. for msgpack, define functions and enable Time support for tag 1
	// mh.SetExt(reflect.TypeOf(time.Time{}), 1, myExt)

	// create and use decoder/encoder
	var (
	  r io.Reader
	  w io.Writer
	  b []byte
	  h = &bh // or mh to use msgpack
	)

	dec = codec.NewDecoder(r, h)
	dec = codec.NewDecoderBytes(b, h)
	err = dec.Decode(&v)

	enc = codec.NewEncoder(w, h)
	enc = codec.NewEncoderBytes(&b, h)
	err = enc.Encode(v)

	//RPC Server
	go func() {
	    for {
	        conn, err := listener.Accept()
	        rpcCodec := codec.GoRpc.ServerCodec(conn, h)
	        //OR rpcCodec := codec.MsgpackSpecRpc.ServerCodec(conn, h)
	        rpc.ServeCodec(rpcCodec)
	    }
	}()

	//RPC Communication (client side)
	conn, err = net.Dial("tcp", "localhost:5555")
	rpcCodec := codec.GoRpc.ClientCodec(conn, h)
	//OR rpcCodec := codec.MsgpackSpecRpc.ClientCodec(conn, h)
	client := rpc.NewClientWithCodec(rpcCodec)

# Running Tests

To run tests, use the following:

	go test

To run the full suite of tests, use the following:

	go test -tags codec.alltests -run Suite

You can run the tag 'codec.safe' to run tests or build in safe mode. e.g.

	go test -tags codec.safe -run Json
	go test -tags "codec.alltests codec.safe" -run Suite

You can run the tag 'codec.notmono' to build bypassing the monomorphized code e.g.

	go test -tags codec.notmono -run Json

Running Benchmarks

	cd bench
	go test -bench . -benchmem -benchtime 1s

Please see http://github.com/ugorji/go-codec-bench .

# Caveats

Struct fields matching the following are ignored during encoding and decoding
  - struct tag value set to -
  - func, complex numbers, unsafe pointers
  - unexported and not embedded
  - unexported and embedded and not struct kind
  - unexported and embedded pointers (from go1.10)

Every other field in a struct will be encoded/decoded.

Embedded fields are encoded as if they exist in the top-level struct,
with some caveats. See Encode documentation.
*/
package codec

/*
Generics

Generics are used across to board to reduce boilerplate, and hopefully
improve performance by
- reducing need for interface calls (de-virtualization)
- resultant inlining of those calls

encoder/decoder --> Driver (json/cbor/...) --> input/output (bytes or io abstraction)

There are 2 * 5 * 2 (20) combinations of monomorphized values.

Key rules
- do not use top-level generic functions.
  Due to type inference, monomorphizing them proves challenging
- only use generic methods.
  Monomorphizing is done at the type once, and method names need not change
- do not have method calls have a parameter of an encWriter or decReader.
  All those calls are handled directly by the driver.
- Include a helper type for each parameterized thing, and add all generic functions to them e.g.
  helperEncWriter[T encWriter]
  helperEncReader[T decReader]
  helperEncDriver[T encDriver]
  helperDecDriver[T decDriver]
- Always use T as the generic type name (when needed)
- No inline types
- No closures taking parameters of generic types

*/
/*
Naming convention:

Currently, as generic and non-generic types/functions/vars are put in the same files,
we suffer because:
- build takes longer as non-generic code is built when a build tag wants only monomorphised code
- files have many lines which are not used at runtime (due to type parameters)
- code coverage is inaccurate on a single run

To resolve this, we are streamlining our file naming strategy.

Basically, we will have the following nomenclature for filenames:
- fastpath (tag:notfastpath):        *.notfastpath.*.go vs *.fastpath.*.go
- typed parameters (tag:notmono):    *.notmono.*.go vs *.mono.*.go
- safe (tag:safe):                   *.safe.*.go vs *.unsafe.go
- generated files:                   *.generated.go
- all others (tags:N/A):             *.go without safe/mono/fastpath/generated in the name

The following files will be affected and split/renamed accordingly

Base files:
- binc.go
- cbor.go
- json.go
- msgpack.go
- simple.go
- decode.go
- encode.go

For each base file, split into __file__.go (containing type parameters) and __file__.base.go.
__file__.go will only build with notmono.

Other files:
- fastpath.generated.go -> base.fastpath.generated.go and base.fastpath.notmono.generated.go
- fastpath.not.go       -> base.notfastpath.go
- init.go               -> init.notmono.go

Appropriate build tags will be included in the files, and the right ones only used for
monomorphization.
*/
/*
Caching Handle options for fast runtime use

If using cached values from Handle options, then
- re-cache them at each reset() call
- reset is always called at the start of each (Must)(En|De)code
  - which calls (en|de)coder.reset([]byte|io.Reader|String)
  - which calls (en|de)cDriver.reset()
- at reset, (en|de)c(oder|Driver) can re-cache Handle options before each run

Some examples:
- json: e.rawext,di,d,ks,is / d.rawext
- decode: (decoderBase) d.jsms,mtr,str,
*/
